A device for estimating a fixed position of a wireless communication is provided. The device comprises a radio connected to an antenna array, a memory and a process. The radio can receive a first signal transmitted from a first direction by the wireless communication device to the movable device, and a second signal transmitted from a second direction by the wireless communication device to the movable device. The processor can calculate a first angle of arrival (AOA) a second AOA. The processor can estimate the fixed position of the wireless communication device based on the first AOA, the second AOA, the first position and the second position.

An example wireless audio electronic device includes a first antenna, a communication circuit, and a processor. The processor may be configured to receive a positioning signal from an external electronic device through the first antenna so as to obtain first positioning information; obtain, from a different audio device located in a case together with the wireless audio electronic device, second positioning information for the positioning signal received by the different wireless audio electronic device; determine an angle of arrival of the positioning signal based on the first positioning information, the second positioning information, and the distance between the wireless audio electronic device and the different wireless audio electronic device; and transmit a response signal including information of the angle of arrival to the external electronic device.

Provided is a positioning apparatus including a communicator including at least three transceivers that are arranged in a first line; and a processor configured to calculate a first phase difference between reference signals received by a first transceiver pair arranged in the first line, a second phase difference between reference signals received by a second transceiver pair arranged in the first line, and a third phase difference between reference signals received by a third transceiver pair arranged in the first line, to determine an integer ambiguity of the second phase difference and an integer ambiguity of the third phase difference based on the first phase difference, and to calculate a position of an apparatus to be positioned based on the second phase difference, the integer ambiguity of the second phase difference, the third phase difference, and the integer ambiguity of the third phase difference.

Provided is a positioning apparatus including a communicator including at least three transceivers that are arranged in a first line; and a processor configured to calculate a first phase difference between reference signals received by a first transceiver pair arranged in the first line, a second phase difference between reference signals received by a second transceiver pair arranged in the first line, and a third phase difference between reference signals received by a third transceiver pair arranged in the first line, to determine an integer ambiguity of the second phase difference and an integer ambiguity of the third phase difference based on the first phase difference, and to calculate a position of an apparatus to be positioned based on the second phase difference, the integer ambiguity of the second phase difference, the third phase difference, and the integer ambiguity of the third phase difference.

An automatic vehicle positioning management system includes an on-vehicle apparatus and a portable device. The on-vehicle apparatus, installed on a vehicle, acquires a first location of the vehicle through wireless positioning. The first location is sent to the portable device which acquires a second location of the vehicle through GPS. When multiple vehicles form a fleet, each vehicle respectively sends its first and second locations to a server through its portable device. The second location of each vehicle is corrected by operations of point error analysis, image overlay and point error correction, so that the fleet can be managed more precisely.

Methods and devices useful in performing precise indoor localization and tracking are provided. By way of example, a method includes locating and tracking, via a first wireless electronic device, a plurality of other wireless electronic devices within an indoor environment. Location ambiguity mitigation is performed using characteristics of signals received by a reference node used to generate a radio frequency map of electronic devices.

Disclosed are techniques for scheduling uplink (UL) and downlink (DL) physical layer resources for a serving node and a user equipment (UE) for round trip time (RTT) and observed time difference of arrival (OTDOA) based positioning. In an aspect, a serving node and/or a network entity configure the UL and DL physical layer resources, and inform the UE. A network node transmits RTT measurement (RTTM) signal to the UE and receives RTT response (RTTR) signals from the UE. The network node measures the times the RTTM signals are transmitted and the times the RTTR signals are received. The UE provides to serving node processing times indicating a duration between the UE receiving the RTTM signals and the UE transmitting the RTTR signals. The RTTs are calculated from the times measured by the network node and the processing times provided by the UE.

An apparatus for a vehicle includes processing circuitry configured to obtain identification information on a future passenger of the vehicle, the identification information comprising an ultra-wideband communication identification of a mobile device of the future passenger. The processing circuitry is also configured to locate the future passenger outside the vehicle using ultra-wideband communication, the ultra-wideband communication being performed between an ultra-wideband transceiver of the vehicle and the mobile device of the future passenger and being based on the ultra-wideband communication identification of the mobile device. The processing circuitry is further configured to compute guidance information based on the location of the future passenger of the vehicle, and provide the guidance information via an interface.

Detecting unauthorized access of a locked key container having a key for a vehicle or a premises. An indication is received at a sensor coupled to the key that the key container is being tampered with. A notification is sent in response to receiving the indication that the key container is being tampered with.

There is provided a method and apparatus for tracking a device. The tracked device may be a wearable device worn by a user participating in an athletic activity. An anchor device is positioned with respect to a playing area and receives signals from the tracked device. The anchor device estimates the position of the tracked device by measuring a distance and direction of the signal, and decodes the signal to obtain measurements taken by the tracked device. The position and the measurements are combined to produce tracking data for the device.